Mechanism underlying berberine's effects on HSP70/TNFα under heat stress: Correlation with the TATA boxes.

Heat stress can stimulate an increase in body temperature, which is correlated with increased expression of heat shock protein 70 (HSP70) and tumor necrosis factor α (TNFα). The exact mechanism underlying the HSP70 and TNFα induction is unclear. Berberine (BBR) can significantly inhibit the temperature rise caused by heat stress, but the mechanism responsible for the BBR effect on HSP70 and TNFα signaling has not been investigated. The aim of the present study was to explore the relationship between the expression of HSP70 and TNFα and the effects of BBR under heat conditions, using in vivo and in vitro models. The expression levels of HSP70 and TNFα were determined using RT-PCR and Western blotting analyses. The results showed that the levels of HSP70 and TNFα were up-regulated under heat conditions (40 °C). HSP70 acted as a chaperone to maintain TNFα homeostasis with rising the temperature, but knockdown of HSP70 could not down-regulate the level of TNFα. Furthermore, TNFα could not influence the expression of HSP70 under normal and heat conditions. BBR targeted both HSP70 and TNFα by suppressing their gene transcription, thereby decreasing body temperature under heat conditions. In conclusion, BBR has a potential to be developed as a therapeutic strategy for suppressing the thermal effects in hot environments.

Functional architecture of two exclusively late stage pollen-specific promoters in rice (Oryza sativa L.).

Late stage pollen-specific promoters are important tools in crop molecular breeding. Several such promoters, and their functional motifs, have been well characterized in dicotyledonous plants such as tomato and tobacco. However, knowledge about the functional architecture of such promoters is limited in the monocotyledonous plant rice. Here, pollen-late-stage-promoter 1 (PLP1) and pollen-late-stage-promoter 2 (PLP2) were characterized using a stable transformation system in rice. Histochemical staining showed that the two promoters exclusively drive GUS expression in late-stage pollen grains in rice. 5' deletion analysis revealed that four regions, including the -1159 to -720 and the -352 to -156 regions of PLP1 and the -740 to -557 and the -557 to -339 regions of PLP2, are important in maintaining the activity and specificity of these promoters. Motif mutation analysis indicated that 'AGAAA' and 'CAAT' motifs in the -740 to -557 region of PLP2 act as enhancers in the promoter. Gain of function experiments indicated that the novel TA-rich motif 'TACATAA' and 'TATTCAT' in the core region of the PLP1 and PLP2 promoters is necessary, but not sufficient, for pollen-specific expression in rice. Our results provide evidence that the enhancer motif 'AGAAA' is conserved in the pollen-specific promoters of both monocots and eudicots, but that some functional architecture characteristics are different.

[Cloning and analysis of reverse transcriptase(RT) of Ty1-copia retrotransposons in Dendrobium officinale].

Using universal primer Ty1-copia retrotransposon RT,43 Ty1-copia like retrotransposon RT with high heterogeneity, stop codon mutation and frameshift mutation were amplified by PCR from genomic DNA of Zhejiang Lin'an (C15) and Yunnan Guangnan (A39) of Dendrobium officinale. The length of these sequences varied from 260 to 266 bp, and was rich in AT and consistency ranged from 47.1% to 97.7%. Different c/s-acting regulatory elements induced by low temperature, heat, light, all kinds of plant growth regulating substances and the starting transcription signals, corresponding to CAAT box, TATA box conserved sequences and some other regulatory elements. When being translated into amino acids, ten sequences presented stop codon mutation, five sequences presented frameshift mutation, and thirty-seven sequences presented conserved sequence "SLYGKQ" mutation. Six categories were identified through phylogenic analysis after alignment analyses of their amino acid sequences, and with other plants (eg. Triticum aestivum, Eleocharis quinqueflora) having high homology, which indicated that horizontal transmission of retrotransposon occurred among the plants in the past.

Yin and Yang of disease genes and death genes between reciprocally scale-free biological networks.

Biological networks often show a scale-free topology with node degree following a power-law distribution. Lethal genes tend to form functional hubs, whereas non-lethal disease genes are located at the periphery. Uni-dimensional analyses, however, are flawed. We created and investigated two distinct scale-free networks; a protein-protein interaction (PPI) and a perturbation sensitivity network (PSN). The hubs of both networks exhibit a low molecular evolutionary rate (P < 8 × 10(-12), P < 2 × 10(-4)) and a high codon adaptation index (P < 2 × 10(-16), P < 2 × 10(-8)), indicating that both hubs have been shaped under high evolutionary selective pressure. Moreover, the topologies of PPI and PSN are inversely proportional: hubs of PPI tend to be located at the periphery of PSN and vice versa. PPI hubs are highly enriched with lethal genes but not with disease genes, whereas PSN hubs are highly enriched with disease genes and drug targets but not with lethal genes. PPI hub genes are enriched with essential cellular processes, but PSN hub genes are enriched with environmental interaction processes, having more TATA boxes and transcription factor binding sites. It is concluded that biological systems may balance internal growth signaling and external stress signaling by unifying the two opposite scale-free networks that are seemingly opposite to each other but work in concert between death and disease.

Analysis of phosphorus-deficient responsive miRNAs and cis-elements from soybean (Glycine max L.).

Phosphorus is one of the major factors controlling plant growth and productivity. Although physiological and molecular processes of P deficiency have been intensively investigated, our current understanding of the coordinated regulation of phosphate-responsive genes and signal networks is limited. In the present study, we performed a microarray-based genome-wide transcriptional analysis of miRNAs from soybean (Glycine max L.) under phosphate deficiency. miRNAs extracted from P-deficient and P-sufficient soybean were hybridized to an array containing 853 known plant miRNA sequences. An induction ratio significant at p<0.01 was observed for 57 miRNAs belonging to 27 families. Among these miRNA families, which differentially expressed, 7 and 8 were found to be up-regulated, whereas 17 and 6 were down-regulated in leaves and roots, respectively. Seven representative individual miRNAs were selected for qRT-PCR validation, and most showed an expression pattern similar to that on microarray. We further predicted P-responsive cis-elements from the promoters of miRNAs in response to and non-responding to P deficiency. In total, 125 putative cis-elements were identified for 24 soybean P-deficient responsive miRNAs. Interestingly, those miRNAs (54) not responding to P deficiency were also found to contain the same P-responsive motifs. A comparative analysis revealed that the frequency of the motif occurrence in the promoters of miRNA genes in response to P deficiency was higher than that of miRNA genes not responding to P deficiency. Our study provides initial evidence in soybean that a set of miRNAs with a high frequency of P-responsive cis-elements may coordinately regulate the plant response to P deficiency.

Molecular characterization of the phenol oxidase (pox2) gene from the ligninolytic fungus Pleurotus ostreatus.

The gene (pox2) encoding a phenol oxidase from Pleurotus ostreatus, a lignin-degrading basidiomycete, was sequenced and the corresponding pox2-cDNA was also synthesized, cloned and sequenced. The isolated gene consisted of 2674 bp, with the coding sequence interrupted by 19 introns and flanked by an upstream region in which the putative metal-responsive elements (MREs) were determined in the promoter region (849 bp), where MRE 1, 2, 3 and 4 were located in positions -20, -60, -236 and -297. A functional TATA consensus sequence was recognized in position -85, while CAAT and its inversion consensus sequences were recognized in positions -284, -554, -689 and -752. The putative GC box consensus sequences were recognized in positions -181 and -460, and xenobiotic-responsive elements in positions -107, -277 and -390. The isolation of a second cDNA (pox2-cDNA), the nucleotide sequence of pox2, was found to contain an ORF of 1665 bp capable of coding for a protein of 533 amino acid residues. Northern blot analysis revealed that strong transcriptional induction was observed in the copper-supplemented cultures for the pox2 gene.

Characterization of sINR, a strict version of the Initiator core promoter element.

The proximal promoter consists of binding sites for transcription regulators and a core promoter. We identified an overrepresented motif in the proximal promoter of human genes with an Initiator (INR) positional bias. The core of the motif fits the INR consensus but its sequence is more strict and flanked by additional conserved sequences. This strict INR (sINR) is enriched in TATA-less genes that belong to specific functional categories. Analysis of the sINR-containing DHX9 and ATP5F1 genes showed that the entire sINR sequence, including the strict core and the conserved flanking sequences, is important for transcription. A conventional INR sequence could not substitute for DHX9 sINR whereas, sINR could replace a conventional INR. The minimal region required to create the major TSS of the DHX9 promoter includes the sINR and an upstream Sp1 site. In a heterologous context, sINR substituted for the TATA box when positioned downstream to several Sp1 sites. Consistent with that the majority of sINR promoters contain at least one Sp1 site. Thus, sINR is a TATA-less-specific INR that functions in cooperation with Sp1. These findings support the idea that the INR is a family of related core promoter motifs.

Promoter features related to tissue specificity as measured by Shannon entropy.

BACKGROUND: The regulatory mechanisms underlying tissue specificity are a crucial part of the development and maintenance of multicellular organisms. A genome-wide analysis of promoters in the context of gene-expression patterns in tissue surveys provides a means of identifying the general principles for these mechanisms. RESULTS: We introduce a definition of tissue specificity based on Shannon entropy to rank human genes according to their overall tissue specificity and by their specificity to particular tissues. We apply our definition to microarray-based and expressed sequence tag (EST)-based expression data for human genes and use similar data for mouse genes to validate our results. We show that most genes show statistically significant tissue-dependent variations in expression level. We find that the most tissue-specific genes typically have a TATA box, no CpG island, and often code for extracellular proteins. As expected, CpG islands are found in most of the least tissue-specific genes, which often code for proteins located in the nucleus or mitochondrion. The class of genes with no CpG island or TATA box are the most common mid-specificity genes and commonly code for proteins located in a membrane. Sp1 was found to be a weak indicator of less-specific expression. YY1 binding sites, either as initiators or as downstream sites, were strongly associated with the least-specific genes. CONCLUSIONS: We have begun to understand the components of promoters that distinguish tissue-specific from ubiquitous genes, to identify associations that can predict the broad class of gene expression from sequence data alone.

A leader intron and 115-bp promoter region necessary for expression of the carnation S-adenosylmethionine decarboxylase gene in the pollen of transgenic tobacco.

The expression of CSDC9 encoding S-adenosylmethionine decarboxylase (SAMDC) is developmentally and spatially regulated in carnation. To examine the regulation of the SAMDC gene, we analyzed the spatial expression of CSDC9 with a 5'-flanking beta-glucuronidase fusion in transgenic tobacco plants. GUS was strongly expressed in flower, pollen, stem and vein of cotyledons. Expression in both anther and stigma was under developmental control; analysis of a series of mutants with deletions of the 5'-flanking region demonstrated differential activation in petal, anther, stigma and pollen grains. All the major cis-regulatory elements required for pollen-specific transcription were located in the upstream region between -273 and -158. This region contains four putative elements related to gibberellin induction (pyrimidine boxes, TTTTTTCC and CCTTTT) and pollen-specific expression (GTGA and AGAAA). In addition, the first 5'-leader intron was necessary for tissue-specific expression.

Cloning, gene organization and identification of an alternative splicing process in lecithin:retinol acyltransferase cDNA from human liver.

Lecithin:retinol acyltransferase (LRAT) catalyzes the synthesis of retinyl esters in many tissues and is crucial for the transport and intracellular storage of vitamin A. LRAT expression is highly regulated in the liver. In this study, we have cloned and sequenced the full-length LRAT mRNA from human liver and identified its 5'- and 3'-ends. Full-length LRAT mRNA comprises 5023 nt with a predicted ORF of 230 amino acids, a short 5'UTR, and a relatively long 3'UTR of 4 kb containing several polyadenylation signals and AU-rich regions. Based on alignment of this mRNA with human genomic DNA in the GenBank database, the human LRAT gene spans about 9.1 kbp and consists of two exons and a relatively long 4-kbp intron. Further analysis of normal liver revealed a minor alternative splicing variant which lacks a 103 nt polynucleotide contained in the 5'UTR of the full-length LRAT transcript. This variant predicts that the LRAT gene is organized into three exons and two introns, as reported for LRAT cloned from retinal pigment epithelium (RPE) cells. These two LRAT mRNA variants are also present in testis, which is known to express LRAT and contain retinyl esters. Major and minor transcription start sites for human liver LRAT mRNA were identified and the sequence of the upstream proximal promoter region was retrieved from the GenBank database and physically analyzed for the presence of putative cis-acting elements essential for basal transcription. This region contains a TATA box, CCAAT box and Sp1 site, which are apparently conserved in mouse and rat LRAT genes. Our results provide evidence that multiple LRAT mRNA transcripts, which are expressed in a tissue-specific manner, may result from several mechanisms including differential splicing of the 5'UTR region and the use of multiple polyadenylation signals in the 3'UTR.

The Zap1 transcriptional activator also acts as a repressor by binding downstream of the TATA box in ZRT2.

The zinc-responsive transcriptional activator Zap1 regulates the expression of both high- and low-affinity zinc uptake permeases encoded by the ZRT1 and ZRT2 genes. Zap1 mediates this response by binding to zinc-responsive elements (ZREs) located within the promoter regions of each gene. ZRT2 has a remarkably different expression profile in response to zinc compared to ZRT1. While ZRT1 is maximally induced during zinc limitation, ZRT2 is repressed in low zinc but remains induced upon zinc supplementation. In this study, we determined the mechanism underlying this paradoxical Zap1-dependent regulation of ZRT2. We demonstrate that a nonconsensus ZRE (ZRT2 ZRE3), which overlaps with one of the ZRT2 transcriptional start sites, is essential for repression of ZRT2 in low zinc and that Zap1 binds to ZRT2 ZRE3 with a low affinity. The low-affinity ZRE is also essential for the ZRT2 expression profile. These results indicate that the unusual pattern of ZRT2 regulation among Zap1 target genes involves the antagonistic effect of Zap1 binding to a low-affinity ZRE repressor site and high-affinity ZREs required for activation.

A telomerase-dependent conditionally replicating adenovirus for selective treatment of cancer.

The catalytic component of human telomerase reverse transcriptase (hTERT) is not expressed in most primary somatic human cells, whereas the majority of cancer cells reactivate telomerase by transcriptional up-regulation of hTERT. Several studies demonstrated that the hTERT promoter can be used to restrict gene expression of E1-deleted replication defective adenoviral vectors to telomerase-positive cancer cells. In this study, a conditionally replicating adenovirus (hTERT-Ad) expressing E1A genes under control of a 255-bp hTERT-promoter was constructed. Additionally, an internal ribosomal entry site-enhanced green fluorescent protein cassette was inserted downstream of the E1B locus to monitor viral replication in vivo. Adenoviral replication of hTERT-Ad and enhancement of enhanced green fluorescent protein expression could be observed in all investigated telomerase-positive tumor cell lines. In contrast, hTERT-Ad infection of telomerase-negative primary human hepatocytes did not result in significant replication. The capability of hTERT-Ad to induce cytopathic effects in tumor cells was comparable with that of adenovirus wild type and significantly higher compared with ONYX-015, regardless of the p53 status of the tumor cells. Single application of low-dose hTERT-Ad to tumor xenografts led to significant inhibition of tumor growth, confirming the potential therapeutic value of conditionally replicative adenoviral vectors. These in vivo experiments also revealed that hTERT-Ad-mediated oncolysis was more efficient than ONYX-015 treatment. These results demonstrate that expression of E1A under transcriptional control of the hTERT promoter is sufficient for effective telomerase-dependent adenovirus replication as a promising perspective for the treatment of the majority of epithelial tumors.

Expression and promoter activation of the Rpe65 gene in retinal pigment epithelium cell lines.

PURPOSE: To examine the expression and promoter activation of the retinal pigment epithelium (RPE)-preferentially expressed Rpe65 gene in the commonly available RPE cell lines. METHODS: Reverse transcription coupled to polymerase chain reaction (RT-PCR) was performed after total RNA extraction from different RPE (ARPE-19, monkey, hTERT-RP1 and D407) and non-RPE (COS-7, HeLa, HepG2 and HS27) cell lines. Promoter activity was assayed by transient transfection of luciferase reporter constructs containing nested deletions of the 5' flanking region of the mouse Rpe65 gene. The involvement of a putative TATA box in the basal promoter expression was studied by site-directed mutagenesis in D407 cells and binding of TATA box-related transcription factors to that region was demonstrated by Electrophoretic Mobility Shift Assays (EMSA). RESULTS: Expression of the human RPE65 cDNA was observed in all the RPE cell lines tested, and in COS-7 cells (monkey RPE65 cDNA). Transient transfections of the mouse Rpe65 promoter/luciferase transgene containing nested deletions of the Rpe65 5' flanking region showed that fragments containing bases -655 to +48 and -1240 to +48 generated specific promoter activity only in the D407 cell line. A promoter fragment from -49 to +48 directed basal promoter activity in all the cell lines tested. Part of this basal activity was due to a putative TATA box that specifically binds transcription factors contained in a D407 nuclear extract. CONCLUSIONS: Although transcription of the Rpe65 gene occurs in all the tested cell lines, we find that the D407 cell line is the only one capable of directing specific mouse Rpe65 promoter activity. This limits the study of the transcriptional regulation of the mouse Rpe65 gene in vitro to this particular cell line.

New potent agents binding to a poly(dT) sequence in double-stranded DNA: bis(Zn(2+)-cyclen) and tris(Zn(2+)-cyclen) complexes.

In an effort to search for mechanistically new and more potent agents than conventional drugs that target AT-rich sequences in double-stranded DNA, we have tested multi(Zn(2+)-cyclen) complexes. Indeed, they selectively bound to poly(dT) sequences to melt the A-T hydrogen bonds; only 2.5 microM or 4 microM of the p-tris(Zn(2+)-cyclen) complex were required to completely melt a 50 microM nucleobase of double-stranded poly(dA) x poly(dT) or poly(dA-dT)(2) at 25 degrees C. The region with seven consecutive T's in native DNA (150 bp) was protected from micrococcal nuclease hydrolysis, as revealed by footprinting assays, with IC(50) values of 2 microM for p-bis(Zn(2+)-cyclen) and 0.5 microM for p-tris(Zn(2+)-cyclen). The high affinity to AT-rich sequences of these Zn(2+)-cyclen complexes matches or surpasses those of the conventional AT-binding drugs distamycin A (IC(50)=2 microM) and DAPI (5 microM). Moreover, the p-tris(Zn(2+)-cyclen) complex selectively binds to the TATA box sequence of the SV40 early promoter to inhibit the binding of the TATA binding protein as effectively as distamycin A, with an IC(50) value of 0.4 microM. In vitro transcription of poly(dA) x poly(dT) using Escherichia coli RNA polymerase was effectively inhibited by p-tris(Zn(2+)-cyclen). The [(3)H]-ATP incorporation into RNA was more strongly blocked (IC(50)=0.8 microM) than the [(3)H]-UTP incorporation (IC(50)=40 microM), a fact indicating that the p-tris(Zn(2+)-cyclen) complex interacts only with the poly(dT) strand in the double-stranded DNA template.

Cytosolic glutamine synthetase in soybean is encoded by a multigene family, and the members are regulated in an organ-specific and developmental manner.

Gln synthetase (GS) is the key enzyme in N metabolism and it catalyzes the synthesis of Gln from glutamic acid, ATP, and NH4+. There are two major isoforms of GS in plants, a cytosolic form (GS1) and a chloroplastic form (GS2). In leaves, GS2 functions to assimilate ammonia produced by nitrate reduction and photorespiration, and GS1 is the major isoform assimilating NH3 produced by all other metabolic processes, including symbiotic N2 fixation in the nodules. GS1 is encoded by a small multigene family in soybean (Glycine max), and cDNA clones for the different members have been isolated. Based on sequence divergence in the 3'-untranslated region, three distinct classes of GS1 genes have been identified (alpha, beta, and gamma). Genomic Southern analysis and analysis of hybrid-select translation products suggest that each class has two distinct members. The alpha forms are the major isoforms in the cotyledons and young roots. The beta forms, although constitutive in their expression pattern, are ammonia inducible and show high expression in N2-fixing nodules. The gamma1 gene appears to be more nodule specific, whereas the gamma2 gene member, although nodule enhanced, is also expressed in the cotyledons and flowers. The two members of the alpha and beta class of GS1 genes show subtle differences in the expression pattern. Analysis of the promoter regions of the gamma1 and gamma2 genes show sequence conservation around the TATA box but complete divergence in the rest of the promoter region. We postulate that each member of the three GS1 gene classes may be derived from the two ancestral genomes from which the allotetraploid soybean was derived.

Anabolic steroids, testosterone-precursors and virilizing androgens induce distinct activation profiles of androgen responsive promoter constructs.

Different androgens, e.g. virilizing androgens such as testosterone and its precursors as well as synthetic anabolic steroids, respectively, induce diverse biological effects. The molecular basis for this variety in biological actions, however, is not well understood. We hypothesized that this variability of actions may be due to steroid-specific target gene expression profiles following androgen receptor (AR)-activation. Therefore, we investigated androgen receptor dependent transactivation of three structurally different androgen responsive promoter constructs ((ARE)(2)TATA-luc, MMTV-luc, GRE-OCT-luc) in co-transfected Chinese hamster ovary (CHO)-cells as an artificial model simulating different natural target genes. Three virilizing androgens (dihydrotestosterone, testosterone, methyltrienolone), three anabolic steroids (oxandrolone, stanozolol, nandrolone) and two testosterone-precursors of gonadal and adrenal origin (dehydroepiandrosterone, androstenedione) were used as ligands (0.001-100 nM). All steroids proved to be potent activators of the AR. Remarkably, anabolic steroids and testosterone-precursors showed characteristic promoter activation profiles distinct from virilizing androgens with significantly lower (ARE)(2)TATA-luc activation. Hierarchical clustering based on similarity of activation profiles lead to a dendrogram with two major branches: first virilizing androgens, and second anabolics/testosterone-precursors. We conclude that steroid-specific differences in gene transcription profiles due to androgen receptor activation could contribute to differences in biological actions of androgens.

Expression of TCF, TPF/YY1, and the Sp family transcription factors in rabbit endometrium throughout pregnancy.

BACKGROUND: TCF, TPF/YY1, and the Sp family are specific transcription factors that bind sequences found within the uteroglobin (UG) gene promoter region that are necessary for transcription. To date, UG gene expression and regulation in vivo are not fully understood. The purpose of this study was to assess the expression patterns of these factors in the rabbit endometrium throughout pregnancy. METHODS: Endometrial nuclear extracts were obtained from female rabbits on days 0, 3, 5, 7, 15, and 28 after mating. Transcription factor expression was assessed by DNA-protein binding assays using endometrial nuclear proteins and specific oligonucleotides. Band shifts were observed on 4% acrylamide gels and analyzed by densitometry. RESULTS: The expression patterns of the transcription factors analyzed here differed, as TPF/YY1 and Sp3/SpR-2 were expressed constitutively while TCF and Sp1 showed variable expression patterns throughout pregnancy. CONCLUSIONS: Our results suggest that UG gene expression in the intact pregnant rabbit is controlled by two constitutive and two regulated factors, and that the DNA-binding sites are located at the TATA box and the GT1 sites within the gene promoter.

Leaderless transcripts of the crenarchaeal hyperthermophile Pyrobaculum aerophilum.

We mapped transcription start sites for ten unrelated protein-encoding Pyrobaculum aerophilum genes by primer extension and S(1) nuclease mapping. All of the mapped transcripts start at the computationally predicted translation start codons, two of which were supported by N-terminal protein sequencing. A whole genome computational analysis of the regions from -50 to +50 nt around the predicted translation starts codons revealed a clear upstream pattern matching the consensus sequence of the archaeal TATA box located unusually close to the translation starts. For genes with the TATA boxes that best matched the consensus sequence, the distance between the TATA box and the translation start codon appears to be shorter than 30 nt. Two other promoter elements distinguished were also found unusually close to the translation start codons: a transcription initiator element with significant elevation of C and T frequencies at the -1 position and a BRE element with more frequent A bases at position -29 to -32 (counting from the translation start site). We also show that one of the mapped genes is transcribed as the first gene of an operon. For a set of genes likely to be internal in operons the upstream signal extracted by computer analysis was a Shine-Dalgarno pattern matching the complementary sequence of P. aerophilum 16 S rRNA. Together these results suggest that the translation of proteins encoded by single genes or genes that are first in operons in the hyperthermophilic crenarchaeon P. aerophilum proceeds mostly, if not exclusively, through leaderless transcripts. Internal genes in operons are likely to undergo translation via a mechanism that is facilitated by ribosome binding to the Shine-Dalgarno sequence.

Mapping, characterization, and expression analysis of the SM-20 human homologue, c1orf12, and identification of a novel related gene, SCAND2.

Major psychosis was shown to segregate with a balanced translocation (1q42.1; 11q14.3) in a multigenerational family. This study describes the identification of a human SM-20 homologue gene that lies at about 400 kb on the centromeric side of the 1q42.1 breakpoint. The full-length cDNA sequence and gene structure were determined. Expression analysis was performed, showing high expression levels in skeletal and cardiac muscles; in the central nervous system, expression was restricted to dopaminergic neurons and spinal motoneurons. A second gene displaying high sequence similarity with SM-20 was also identified by BLAST. This gene, located on chromosome 15, is likely to have evolved by retroposition of SM-20 mRNA and an exon-shuffling mechanism. It encodes a 306-amino-acid protein harboring strong homology with an N-terminal motif found in some zinc-finger proteins. This gene was named SCAND2 (SCAN domain-containing 2).

Identification of an enhancer and an alternative promoter in the first intron of the alpha-fetoprotein gene.

In this study we have characterized a positive regulatory region located in the first intron of the alpha-fetoprotein (AFP) gene. We show that the enhancer activity of the region depends on a 44 bp sequence centered on a CACCC motif. The sequence is the target of the two zinc fingers transcription factors BKLF and YY1. The introduction of a mutation destroying the CACCC box impairs the binding of BKLF but improves that of YY1. Moreover, the mutated sequence behaves as a negative control element, suggesting that BKLF behaves as a positive factor and that YY1 is a negative one. We also demonstrate the existence of a novel, tissue-specific AFP mRNA isoform present in the yolk sac and fetal liver which initiates from an alternative promoter located approximately 100 bp downstream of the enhancer element. The transcriptional start site controlled by this new promoter (called P2), was mapped to 66 bp downstream of a TATA box. A putative AUG translation site in-frame with exon 2 of the classical gene was found 295 bp downstream of the transcription start site. Like the traditional AFP promoter (P1), the P2 promoter is active in the yolk sac and fetal liver. Embryonic stem cells with an AFP knock-in gene containing either the P2 promoter or deleted for it were isolated and comparative analysis of embryonic bodies derived from these cells suggests that the P2 promoter contributes to early expression of the AFP gene.